A substrate processing apparatus includes a cover member placed to surround a substrate held by a rotary holder; a collecting member placed in an exhaust path formed between the cover member and the rotary holder; and a solvent supply placed above the collecting member and configured to supply a solvent to the collecting member. The solvent supply includes an inner storage space surrounding the substrate; an outer storage space surrounding the inner storage space; and a partition wall extending along a circumferential direction to partition the inner storage space and the outer storage space. Multiple communication holes are extended to penetrate the partition wall such that the solvent introduced into the outer storage space flows to the inner storage space. Multiple dripping holes are extended to penetrate a bottom wall of the inner storage space such that the solvent within the inner storage space drops toward the collecting member.

The present disclosure proposes an apparatus for coating photoresist and a method for coating photoresist. The apparatus for coating photoresist comprises a gas supply unit (10) configured to supply gas to a photoresist application unit (20); wherein the photoresist application unit (20) comprises: a device cavity (202) enclosed by sidewalls, a bottom plate and a cover plate (206), a rotation platform (204) configured to carry a substrate (205) and bring the substrate to rotate; a guide unit conformal with the substrate, and configured to uniformly blow the gas supplied by the gas supply unit over a surface of the substrate on which the photoresist is coated; and a gas extraction unit (203) configured to extract gas from the device cavity (202). The present disclosure realizes uniformly and rapidly coating the photoresist on a large substrate.

The present disclosure proposes an apparatus for coating photoresist and a method for coating photoresist. The apparatus for coating photoresist comprises a gas supply unit (10) configured to supply gas to a photoresist application unit (20); wherein the photoresist application unit (20) comprises: a device cavity (202) enclosed by sidewalls, a bottom plate and a cover plate (206), a rotation platform (204) configured to carry a substrate (205) and bring the substrate to rotate; a guide unit conformal with the substrate, and configured to uniformly blow the gas supplied by the gas supply unit over a surface of the substrate on which the photoresist is coated; and a gas extraction unit (203) configured to extract gas from the device cavity (202). The present disclosure realizes uniformly and rapidly coating the photoresist on a large substrate.

A method of preventing drippage in a fluid dispensing system. The fluid dispensing system includes a first automatic control valve (ACV), an input of the first ACV connected to fluid-source of fluid, the first ACV having positions ranging from fully closed to fully open, and a second ACV, an input of the second ACV being connected to an output of the first ACV, and an output of the second ACV being connected to a nozzle, the second ACV having positions ranging from fully closed to fully open. The method includes generating a first proxy signal representing at least a first indirect measure of a position of the first ACV. The method includes recognizing, based on at least the first proxy signal that a failure state exists in which the first ACV has failed to close. The method includes causing the second ACV to close when the failure state exists.

A liquid processing device includes: a nozzle configured to discharge, onto a substrate, a processing liquid supplied from a processing liquid source, the processing liquid being configured to process the substrate; a main flow path which connects the processing liquid source and the nozzle; a filter provided in the main flow path; a branch path branched from the main flow path; a pump provided at an end of the branch path; and a controller configured to output a control signal to perform a first process of sucking the processing liquid supplied from the processing liquid source by the pump to flow the processing liquid into the branch path and then a second process of discharging the processing liquid of a smaller amount than a capacity of the branch path from the pump to the branch path to discharge the processing liquid from the nozzle.

In a chamber, first processing is performed as preliminary processing. After the first processing has been finished, the temperature in a predetermined target region in the chamber is measured with a thermographic camera. Then, whether or not to start second processing on a substrate is determined in accordance with the acquired measured temperature information. If it is determined as a result that the second processing can be started, the second processing is performed. In this case, the second processing on the substrate can be started, with the temperature of the target region in the chamber having reached its stability. Accordingly, the second processing can be performed uniformly on a plurality of substrates. That is, it is possible to reduce variations in processing caused by temperature environments in the chamber.

Provided is a substrate treatment apparatus including a treatment container equipped with a conductive member. The conductive member is made of a material having a lower resistivity than that of the treatment container. The conductive member prevents a rise of an electric potential of the treatment container, which is caused by charging during treatment of a substrate, thereby preventing the substrate from being contaminated and damaged by particles and electrostatic arcing.

A manufacturing apparatus for a semiconductor device, the manufacturing apparatus including a spin chuck configured to fix and rotate a wafer; a nozzle configured to spray a chemical toward the wafer; a lateral displacement sensor configured to measure a displacement variation to a lateral surface of the wafer while the spin chuck is being rotated; and a controller configured to control a position of the nozzle by using the displacement variation while the spin chuck is being rotated.

A coating apparatus for forming a coating film over a substrate includes a spin chuck for holding and rotating the substrate, a central coating nozzle over a central portion of the substrate, a plurality of first coating nozzles surrounding the central coating nozzle and spaced apart from the central coating nozzle by substantially a same first distance, and a plurality of second coating nozzles surrounding the central coating nozzle and spaced apart from the central coating nozzle by substantially a same second distance, wherein the second distance is greater than the first distance.

A coating apparatus for forming a coating film over a substrate includes a spin chuck for holding and rotating the substrate, a central coating nozzle over a central portion of the substrate, a plurality of first coating nozzles surrounding the central coating nozzle and spaced apart from the central coating nozzle by substantially a same first distance, and a plurality of second coating nozzles surrounding the central coating nozzle and spaced apart from the central coating nozzle by substantially a same second distance, wherein the second distance is greater than the first distance.